JPH0428927Y2 - - Google Patents

Description

[Detailed description of the invention] (Technical field) This invention relates to an overturning weir that allows water stored in a waterway to be released by overturning a weir plate installed in a waterway as necessary. It is.

(Background technology) The base of the weir plate is pivotally attached to the bottom of the waterway, and the upper end of the weir plate is connected to a wire fed out from a hoisting device provided on the dam, and the weir plate is suspended by this wire.
An overturning weir has been put into practical use that is supported in an upright position, and in the event of a temporary increase in water due to a typhoon, the weir plate can be collapsed to release water stored in the canal. There is. Many of these types of overturning weirs are designed to prevent disasters by automatically overturning the weir plate when the water level of the waterway reaches a predetermined value using, for example, a float. However, the collapsed weir plates remained collapsed even when the flow of water in the canal decreased, so it was necessary for people to go and erect the weir plates every time they fell. What's more, the upright work involves turning the handle of the hoisting device many times to hoist up the weir board.
It was quite hard work. Additionally, if a weir board were to topple over due to a temporary rise in water, the toppling may not be noticed, so it was necessary to look around from time to time to see if there were any abnormalities.

(Purpose of the invention) The present invention was created in view of the above circumstances, and its purpose is to provide an overturning weir in which the overturned weir plate automatically stands up when the flow rate of the waterway falls below a certain level. There is.

(Disclosure of the invention) The overturning weir according to the invention includes a weir plate whose base is pivotally connected to the bottom of a waterway, and the weir plate is raised in an upright state by a hoisting device via a wire attached to the upper end of the weir plate. In the overturning weir, which is constructed so that the weir plate can be overturned to open the waterway if necessary, a hollow container-shaped water tank is provided on the weir plate, and the water tank is filled with water from the waterway. A water inlet through which the water flows in is provided higher than the upper end of the weir plate in the upright state and protrudes further above the upper surface of the weir board in the collapsed state, and a drain port with a smaller diameter than the water inlet is provided to allow water to flow in. The present invention is characterized in that a hoisting force applying means is provided at the lower part of the tank and raises the fallen weir plate when the water tank is empty and no water pressure is applied to the weir plate.

(Example) Fig. 1 is a front view of the overturning weir according to the present invention when water is stored as seen from the upstream side, Fig. 2 is a side view thereof,
FIG. 3 is a plan view of the main part when it is laid down, and FIG. 4 is a side view thereof. The overturning weir G includes a weir plate 2 with a base 2a pivotally attached to the bottom of the waterway 1, a hoisting device 3 installed on the embankment, and a flat plate-like structure provided at the upper end of one side of the weir plate 2. The end of the wire 5 let out from the hoisting device 3 is attached to the attachment piece 4 of the wire.

The weir plate 2 has a frame 10 made by combining aggregates vertically and horizontally, and a round pipe 1 at the top of the frame 10.
1 horizontally, and these frames 1
A steel plate 12 is attached to the upstream side of the round pipe 11. Watertight rubber 14 is attached by bolts 15 to the space between the bottom of the steel plate 12 and the bottom of the waterway 1 and the space between the side of the steel plate 12 and the side of the waterway 1 . The upper half of the weir plate 2 is a water tank 18 formed into a hollow container shape by a frame 10, a round pipe 11, a steel plate 12, a bottom plate 16, and a rear plate 17. A water suction pipe 20 is disposed at the upper end opposite to the mounting piece 4, and a filter 21 for removing dust, etc. is attached to the upstream side of the tip of the water suction pipe 20.
2 is provided. The water suction pipe 20 is supported by a pin 24 so as to be freely rotatable back and forth, and by rotating back and forth along an elongated fitting hole 25 into which the water suction pipe 20 fits, the water suction port 22 height can be changed. In addition, the water suction pipe 20 and the fitting hole 2
5 is closed by an elastic sealing material 26. The water intake port 22 is provided through a through hole 27 provided inside the water intake pipe 20 and the round pipe 11.
It is connected to the water tank 18. Further, at the lower part of the water tank 18, a drain port 28 having a smaller cross-sectional area than the water intake port 22 is provided on the rear plate 17 toward the downstream side.

5 and 6 are a plan view and a side view of the hoisting device. A plurality of rotating shafts, gears, and other parts are housed inside the outer box 30. The pulley shaft 31 provided in the center has a bearing 32,
32', and a weir plate pulley 34 and a weight pulley 35 are attached to both protrusions projecting to the outside of the outer box 30. The end of the weir plate support wire 5 is connected to the weir plate pulley 34 and wound in a predetermined direction. Other weight pulley 3
A weight support wire 36 is wound around the weir plate support wire 5 in the opposite direction to the weir plate support wire 5.
6, a weight 37 is supported in a suspended state within a vertical hole 39 made on the side of the hoisting device 3. A diagonal hole 39a for drainage is provided at the bottom of the vertical hole 39 toward the water channel 1 on the downstream side of the weir plate 2. The weight 37 is also supported by an adjustment wire 41 whose upper end is wound around and fixed to an adjustment pulley 40 installed directly above the vertical hole 39 . During normal water storage, weight 3
7 at a substantially constant ratio, the weight support wire 36
and an adjustment wire 41. By changing the hanging length of the adjustment wire 41, the standing position of the weir plate 2 can be adjusted.

The rotating shaft 45 supported by bearings 44, 44' is a secondary shaft, and the rotation of the pulley shaft 31 is doubled by meshing the gear 46 of the secondary shaft 45 and the gear 47 of the pulley shaft 31. It is transmitted to the next shaft 45 in a decelerating manner. A spring expansion/contraction pulley 49 is attached to the secondary shaft 45, and a spring expansion/contraction wire 50 is connected to the pulley 49. On the other hand, the mounting frame 52 provided on the outer surface of the outer box 30 has a spring storage cylinder 53.
is attached, and the spring 5 is installed in the spring storage tube 53.
4 is loosely fitted. Both ends of the spring 54 are positioned by abutting against the mounting frame 52 and a pressing plate 56 that is slidably fitted into the spring storage cylinder 53. The spring expansion/contraction wire 50 is attached to the outer box 30 and the mounting frame 52.
It is connected to this pressing plate 56 through the through holes 30a, 52a and the inside of the spring 54. Note that the mounting frame 52 is provided with an adjustment bolt 57 for adjusting the installation position of the mounting frame 52.
Further, the spring storage tube 53 is provided with a stopper position adjustment screw 58 for adjusting the length of the spring 54 when it is fully extended. The weight 37 and the spring 54 function as a hoisting force applying means for raising the fallen weir plate.

The winding shaft 60, which is provided on the opposite side of the secondary shaft 45 with the pulley shaft 31 in between, has bearings 61, 61'.
is supported by. A gear 63 and a ratchet wheel 64 are fitted onto the winding shaft 60, and the end opposite to the waterway protrudes from the outer box 30, and the tip thereof becomes a square rod portion 60a. Gear 6 above
3 meshes with the gear 65 of the pulley shaft 31. Further, a pin 6 is provided on the side of the ratchet wheel 64.
A claw-shaped stopper 68 is provided which is pivotally supported by 7. This stopper 68 is not normally engaged with the ratchet wheel 64, but if necessary, it can be brought into engagement with the ratchet wheel 64 as shown in FIG. 7 by pressing with a leaf spring 69. can. By engaging the stopper 68 with the ratchet wheel 64 in this manner, the winding shaft 60 can only rotate in one direction (the winding direction). That is, the ratchet wheel 64 serves as a restraining means for restraining the free rotation of the winding shaft 60 and pulley shaft 31 during manual winding. Instead of configuring as in this example, the ratchet wheel and stopper are kept engaged at all times, and gears 63 and 65 are used only during manual winding.
It may be configured so that the two mesh with each other. Moreover, another gear may be interposed between the pulley shaft 31 and the hoisting shaft 60 as needed, so that the force necessary for hoisting the weir plate 2 can be further reduced.

An oil brake 70 is attached to the side wall of the outer box 30, and a sprocket wheel 72 fitted onto its rotating shaft 71 is connected to a sprocket wheel 73 of the pulley shaft 31 by a chain 75. In the figure, 76 is an idle roller for adjusting the tension of the chain 75. The rotational speed of the pulley shaft 31 is regulated by this oil brake 70.

Next, the operation of this overturning weir G will be explained. During normal water storage, the weir plate 2 is supported in an upright state, and water on the upstream side flows out over the weir plate 2 little by little to the downstream side. At this time, a force is applied to the weir plate support wire 5 in the direction of overturning the weir plate 2 due to the weight of the weir plate itself and water pressure. On the other hand, the weight wire 36 is loaded with enough weight to balance the force of the weight 37 to overturn the weir plate, and the weir plate 2 comes into contact with the stopper 80 and remains stationary. . Note that the weight remaining after subtracting the weight applied to the weight wire 36 from the weight of the weight 37 is applied to the adjustment wire 41.

Waterways rise due to showers, etc., causing the water level to overturn.
When WL ₁ is exceeded, a portion of the flowing water flows into the water tank 18 from the water intake port 22. Since the amount flowing in is greater than the amount flowing out from the drain port 28, water is gradually stored in the water tank 18. Accordingly, the weight of the weir plate 2 increases, and the force in the overturning direction increases. Then, when the force in the falling direction exceeds the force in the standing direction due to the full load of the weight 37, the weir plate 2 starts to fall. As the weir plate 2 falls over and approaches the horizontal position, the force in the falling direction increases, but at the same time, the spring expansion/contraction wire 50 is wound around the pulley 49 due to the rotation transmitted from the pulley shaft 31 to the secondary shaft 45. and the spring 54 contracts. Then, the repulsive force of the spring 54 generated at this time acts in a direction to prevent the pulley shaft 31 from rotating. This repulsive force increases as the overturning of the weir plate 2 progresses, so there is an effect that no sudden force is applied to the oil brake 70.

As shown in FIGS. 3 and 4, the completely collapsed weir plate 2 rests on a cushion rubber 81 provided at the bottom of the waterway, and is parallel to the bottom of the waterway. When the water level in the waterway 2 decreases due to the discharge and finally becomes lower than the standing water level WL ₂ , almost no water flows into the water tank 18 from the water intake port 22, and the outflow amount from the drain port exceeds this inflow amount. Therefore, the water in the water tank 18 gradually decreases. This reduces the weight of the weir plate 2 and reduces the force in the falling direction, but when this force becomes less than the force in the upright direction due to the weight 37 and the spring 54, the weir plate 2 automatically rolls up. It will be done. The repulsive force of the spring 54 is at its maximum when it is collapsed.

As the weir plate 2 rises, the force in the overturning direction decreases, but at the same time, the repulsive force of the spring 54 also decreases, so the weir plate 2 does not suddenly rise. While the weir plate support wire 5 is wound around the pulley 34 one after another, the weight wire 36 is wound around the pulley 34.
When the length of the weight wire 36 becomes equal to the length of the adjustment wire 41, the weight 37
Since the load is also distributed to the adjustment wire 41,
At this position, the force in the falling direction and the force in the rising direction are balanced, and the weir plate 2 comes to rest. Therefore, as described above, by changing the amount of the adjusting wire 41 wound around the adjusting pulley 40, the standing height of the weir plate 2 can be adjusted.

Furthermore, in this example, the water suction pipe 20 is rotatable, and the height of the water suction port 22 can be adjusted arbitrarily, so that the overturning water level WL ₁ and the standing water level can be adjusted.
WL ₂ can be changed. The height of the water suction port may be adjusted by sliding the water suction pipe in the protruding direction.

If the weir plate 2 becomes entangled with dirt and does not automatically stand up, or if it must be forced to stand up for some reason, use a handle with a square hole in the square bar 60a of the hoisting shaft 60. Fit the
Manually roll up the weir plate 2. At this time, the stopper 68 may be engaged with the ratchet wheel 64 so that the winding shaft 60 and the pulley shaft 31 can rotate only in the winding direction.

(Effect of the invention) As is clear from the above explanation, the present invention provides a water tank that automatically sucks and drains water to the weir plate, so that the weir plate automatically overturns when a predetermined overturning water level is reached. In addition, we have realized an overturning weir in which the weir plate stands up when the water level reaches a predetermined standing water level.

[Brief explanation of the drawing]

Figure 1 is a front view of the overturning weir according to the present invention when water is stored as seen from the upstream side, Figure 2 is a side view thereof,
FIG. 3 is a plan view of the main part when it is collapsed, and FIG. 4 is a side view thereof. In addition, Fig. 5 is a plan view of the hoisting device, Fig. 6 is an explanatory diagram of the device, and Fig. 7 is a plan view of the hoisting device.
The figure is an enlarged view of the main parts. 1... Channel, 2... Weir plate, 3... Hoisting device,
5... Weir plate support wire, 18... Water tank, 20
... Water intake pipe, 22 ... Water intake port, 28 ... Drain port,
30... Outer box, 31... Pulley shaft, 34, 40,
49... Pulley, 36... Weight support wire, 37...
... Weight, 41 ... Adjustment wire, 45 ... Secondary shaft,
50... Spring expansion/contraction wire, 54... Spring, 56
...Pushing plate, 60...Hoisting shaft, G...Tipping weir.

Claims (1)

[Scope of utility model registration request] The weir plate, which has a hollow container-shaped water tank with a water intake port for letting water from the waterway flow in and a drain port for discharging the water inside, and whose base is pivotally attached to the bottom of the waterway, is raised to an upright state via a wire using a hoisting device. In an overturning weir configured to be able to open a waterway by overturning the weir as necessary, the water intake port is set higher than the upper end of the weir board in the upright state. The water tank is provided so as to protrude above the top surface, and the drain port is formed to have a smaller diameter than the water intake port and is provided at the bottom of the water tank.
An overturning weir further comprising a hoisting force applying means for applying a rotational force in a direction to erect the weir plate to the wire hoisting rotating shaft of the hoisting device.